81 |
ELECTRONIC DEVICE CONTROL BUTTON OF VEHICLE |
US14740225 |
2015-06-15 |
US20150364279A1 |
2015-12-17 |
Young Jin LEE |
An electronic device control button of a vehicle includes: i) a jog-shuttle configured to control an electronic device including a navigation device for the vehicle; ii) a base part configured to rotatably support the jog-shuttle and slidably move in upward and downward directions from a reference position on a center fascia panel; iii) a return spring provided on the center fascia panel, configured to limit movement of the jog-shuttle, and to recover the jog-shuttle to the reference position; and iv) a terminal part provided at the jog-shuttle and configured to make contact with or be separated from a slot of a circuit board to apply and block different electrical signals to and from the electronic device. |
82 |
CONTROL DEVICE FOR A CRAWLER VEHICLE |
US13882349 |
2011-10-28 |
US20140013892A1 |
2014-01-16 |
Fabio Pescione; Enrico Conti; Sergio Magrini |
A control device for a crawler vehicle, comprising a control lever activated by an operator about a fulcrum and having a free end, the control lever being displaceable along a longitudinal direction of the vehicle between a proximal position closer to the operator and a distal position further from the operator in order to control a main clutch of the vehicle, the control device further comprising a support element suitable for being fixed to a body of the vehicle in order to support an operator's hand when the hand acts on the control lever, wherein the control lever has an intermediate portion interposed between the free end and the fulcrum, the intermediate portion being so shaped as to partially embrace the support element in the proximal position. |
83 |
VEHICLE-OPERATING APPARATUS |
US14001884 |
2012-02-28 |
US20130327174A1 |
2013-12-12 |
Gyo Jun |
A vehicle driving apparatus where brake and acceleration functions are combined with a single stick includes: a lever moving to an acceleration position, an idle position, or a brake position as rotating forward and rearward about a shaft fixed to a vehicle body at a predetermined angle; a hand acceleration means opening an engine throttle to cause a vehicle to be accelerated; a hand brake means pushing a booster rod of a brake booster so that a brake operates to cause the vehicle to be stopped; a guide means installed on the left and right sides of the lever to prevent the lever from being shaken leftward and rightward; a hand brake locking means allowing the hand brake to be continuously applied; and a cruise control means allowing the lever to stay in the acceleration position even if the driver takes his hand off the lever. |
84 |
CONTROL SYSTEM WITH DISPLACEABLE KNOB |
US13876487 |
2011-09-26 |
US20130199901A1 |
2013-08-08 |
Julien Kreider; Emilie Collin |
Control system (10) intended for the choice and the selection of functions in a vehicle, the system (10) comprising a case (14), a lever extending along a main axis from a first end, mounted pivoting about a pivot axis (L, T) to a second end provided with an actuation knob (12), the lever being able to turn about the main axis, and an elastic return device of the lever into a neutral position comprising an action surface in the form of a truncated cone of revolution, the axis of which is the main axis and, on a pivoting of the lever, the active zone is displaced along a generatrix of the cone moving towards the vertex, the elastic means being more biased than in a neutral position. |
85 |
INPUT DEVICE AND ITS MANUFACTURING METHOD |
US12497704 |
2009-07-06 |
US20090265927A1 |
2009-10-29 |
Hiroshi YAJIMA; Etsuo OOBA; Fumiaki KARASAWA; Atsuomi INUKAI |
The integrated structure of the stress sensor section with the control section facilitates the confirmation of the matching of both sections before the input device is incorporated into an electronic device. For example, it is possible to select only the input device which exhibits favorable matching as a result of the confirmation and to incorporate it in the electronic device. Therefore, with the above-described structure of the present invention, an input device that enables constantly favorable matching of both the stress sensor section and the control section can be provided. |
86 |
Input device and its manufacturing method |
US11448518 |
2006-06-07 |
US20090100670A1 |
2009-04-23 |
Hiroshi Yajima; Etsuo Ooba; Fumiaki Karasawa; Atsuomi Inukai |
The integrated structure of the stress sensor section with the control section facilitates the confirmation of the matching of both sections before the input device is incorporated into an electronic device. For example, it is possible to select only the input device which exhibits favorable matching as a result of the confirmation and to incorporate it in the electronic device. Therefore, with the above-described structure of the present invention, an input device that enables constantly favorable matching of both the stress sensor section and the control section can be provided. |
87 |
Input device and methods and systems for same |
US10965505 |
2004-10-14 |
US06920041B2 |
2005-07-19 |
Glen A Oross; Memphis Zhihong Yin |
Computing devices and related input devices are described. In one exemplary embodiment, the computing device is a portable computing device which includes a housing and a deployable input device attached to the housing, wherein the deployable input device can be deployed from a stowed position to an extended position without changing a desktop footprint of the computing device, and wherein the deployable input device is rotatable about an axis for generating input signals. |
88 |
Input device and methods and systems for same |
US10138625 |
2002-05-03 |
US06826042B2 |
2004-11-30 |
Glen A Oross; Memphis Zhihong Yin |
Methods and systems for an input device are described. In one exemplary embodiment, the input device can comprise a housing and a deployable input device attached to the housing. The deployable input device can be deployed from a stowed position to an extended position without changing a desktop footprint of the computing device. |
89 |
Input device and methods and systems for same |
US10138625 |
2002-05-03 |
US20030206151A1 |
2003-11-06 |
Glen
A.
Oross; Memphis
Zhihong
Yin |
Methods and systems for an input device are described. In one exemplary embodiment, the input device can comprise a housing and a deployable input device attached to the housing. The deployable input device can be deployed from a stowed position to an extended position without changing a desktop footprint of the computing device. |
90 |
Rotary electronic component with push switch |
US628809 |
1996-04-05 |
US5711415A |
1998-01-27 |
Tetsuya Fukuda; Tetsuji Ryu |
The present invention provides a rotary electronic component with a push switch which includes a single control knob for assuredly and individually operating a rotary component portion and a push switch. The rotary electronic component with the push switch comprises a rotary component portion such as an encoder portion including a rotary body horizontally rotatable in a fixed position, a knob shaft, a control knob fitted concentrically around the outer periphery of the knob shaft, a resilient portion disposed between the knob shaft and the inner periphery of the control knob, and a push switch portion located outside the control knob, wherein the rotary component portion is actuated by the horizontal rotation of the control knob and the push switch portion is actuated by the horizontal movement of the control knob. |
91 |
Manipulating device having three degree freedom |
US364910 |
1994-12-27 |
US5583407A |
1996-12-10 |
Hiromitsu Yamaguchi |
A manipulating foot pedal device used with a video game machine or the like is operable to provide a three-dimensional operation. The device includes a base member movable in a forward/backward direction relative. A rotatable member is mounted on a top of the base member and rotatable about a first axis extending in a direction perpendicular to the forward/backward direction; a pivotal member mounted on a top of the rotatable member and pivotable about a second axis extending in a direction perpendicular to the first axis. The device further includes first, second, and third detectors operable to detect a moved amount of the base member, a rotated amount of the rotatable member, and a pivoted amount of the pivotal member. |
92 |
Single lever multiple function control mechanism |
US997112 |
1992-12-24 |
US5232057A |
1993-08-03 |
Mark A. Renard |
A control mechanism for actuating multiple valve spools with a single control lever includes a frame member to which a valve assembly having multiple valve spools is assembled. A fixed shaft is mounted in a spaced parallel relationship to said valve spools, with a plurality of motion transfer devices mounted to the fixed shaft which are connected at one end to the valve spools. The other ends of the motion transfer devices are connected to an adapter which is mounted to a spherical pivot in such a way that only one of the valve spools is operated when the lever is reciprocated in a first control direction, only one other valve spool is operated when the lever is reciprocated in a second control direction, and only another valve spool is operated when the lever is twisted up to a predetermined amount. The first, second and third valve spools can be operated one at a time, two at a time or all at once. Additionally, the control mechanism provides for additional motion transfer devices and valve spools to be mounted for operation by auxiliary levers to conveniently provide for additional functions. |
93 |
Control linkage |
US454694 |
1982-12-30 |
US4615232A |
1986-10-07 |
Janaki R. Puppala |
An improved control linkage assembly is disclosed which is particularly suited for embodiment in association with a material handling implement having a reversibly operable mechanism. The assembly includes an operating lever movable from a neutral position in one of two operating directions eminating from a common neutral position and extending in generally the same direction away from the neutral position. The operating lever is selectively engageable with one of two engaging levers for selectively moving a control element of a control member, such as a hydraulic valve, in one of two opposite directions. This type of movement is effected by a series of mechanical linkages which rotate an intermediate shaft clockwise and counterclockwise facilitating movement of the control element in first and second directions. |
94 |
Remote control arrangement |
US222454 |
1981-01-05 |
US4374597A |
1983-02-22 |
Haruo Mochida |
A stopper is provided on the inner wire of a Bowden cable type arrangement. The stopper allows the wire to be pulled in a first axial direction to operate one of two latch mechanisms and engages a shoulder defined in the second latch mechanism when driven in a second axial direction to produce a reaction which causes the tubular housing disposed about the wire between the second latch mechanism and a single handled actuating mechanism, to flex and pull a lever of the second latch mechanism for operating same, whereby a single lever can be used to selectively operate two different mechanisms. |
95 |
Differential and push-pull control system |
US795534 |
1977-05-10 |
US4152950A |
1979-05-08 |
William D. Langford |
A two cable differential and push-pull system uses both cables simultaneously to operate a controlled device. The two cables are tensioned together or pushed together, or one cable is tensioned while the other is pushed, to operate a single device. Controls which have used separate cables for separate functions use paired cables for the multiple functions, reducing stress on individual cables without increasing the number of cables in the installation. In the illustrated transmission control a differential motion, which includes pushing and pulling forces, is applied through the cables to select a rail. A coincident pushing or pulling force is applied through both cables to shift the rail. |
96 |
Lever mechanism |
US815386 |
1977-07-13 |
US4140027A |
1979-02-20 |
Ronald E. Wineburner; Norman R. Allen |
A single control lever mounted on a pivot assembly is movable in an arc in first and second directions in one plane to impart motion through a cam arrangement to a first push rod and cable assembly so that the first push rod and cable assembly moves proportionally to the movement of the lever in either the first or second direction. The same control lever is movable in an arc in third and fourth directions in a second plane normal to the first plane to impart longitudinal motion to a second push rod and cable assembly affixed to the pivot assembly. A resilient means is incorporated in the pivot assembly to resiliently bias the single control lever to a neutral position in the first plane. A gating plate is affixed to the bracket supporting the pivot assembly and limits the travel of the single control lever to a predetermined path. |
97 |
Single knob heater control |
US51376165 |
1965-12-14 |
US3355960A |
1967-12-05 |
FRANK BURECK; CALEY DONALD A |
|
98 |
Permutation member tooth design |
US61685156 |
1956-10-18 |
US2895337A |
1959-07-21 |
MORING JR WALTER G; GRAY GEOFFREY T |
|
99 |
Control mechanism |
US39142553 |
1953-11-12 |
US2865220A |
1958-12-23 |
BAYLEY GEORGE R |
|
100 |
Combined control for radio receivers |
US22015751 |
1951-04-10 |
US2605643A |
1952-08-05 |
PIERRE LEBRETON |
|